starch extraction from palm stems Starch is the most common
carbohydrate in the human diet and is contained in many
staple foods. The major sources of starch intake worldwide are the
cereals (
rice,
wheat, and
maize) and the
root vegetables (
potatoes and
cassava). Many other starchy foods are grown, some only in specific climates, including
acorns,
arrowroot,
arracacha,
bananas,
barley,
breadfruit,
buckwheat,
canna,
colocasia,
cuckoo-pint,
katakuri,
kudzu,
malanga,
millet,
oats,
oca,
polynesian arrowroot,
sago,
sorghum,
sweet potatoes,
rye,
taro,
chestnuts,
water chestnuts, and
yams, and many kinds of
beans, such as
favas,
lentils,
mung beans,
peas, and
chickpeas. Before processed foods, people consumed large amounts of uncooked and unprocessed starch-containing plants, which contained high amounts of
resistant starch. Microbes within the large intestine ferment or consume the starch, producing
short-chain fatty acids, which are used as energy, and support the maintenance and growth of the microbes. Upon cooking, starch is transformed from an insoluble, difficult-to-digest granule into readily accessible glucose chains with very different nutritional and functional properties. In current diets, highly processed foods are more easily digested and release more glucose in the small intestine—less starch reaches the large intestine and more energy is absorbed by the body. It is thought that this shift in energy delivery (as a result of eating more processed foods) may be one of the contributing factors to the development of metabolic disorders of modern life, including obesity and diabetes. The amylose/amylopectin ratio, molecular weight and molecular fine structure influences the physicochemical properties as well as energy release of different types of starches. In addition, cooking and food processing significantly impacts starch digestibility and energy release. Starch has been classified as rapidly digestible starch, slowly digestible starch and resistant starch, depending upon its digestion profile. Raw starch granules resist digestion by human enzymes and do not break down into glucose in the small intestine - they reach the large intestine instead and function as
prebiotic dietary fiber. When starch granules are fully gelatinized and cooked, the starch becomes easily digestible and releases glucose quickly within the small intestine. When starchy foods are cooked and cooled, some of the glucose chains re-crystallize and become resistant to digestion again. Slowly digestible starch can be found in raw cereals, where digestion is slow but relatively complete within the small intestine. Widely used prepared foods containing starch are
bread,
pancakes,
cereals,
noodles,
pasta,
porridge and
tortilla. During cooking with high heat, sugars released from starch can react with amino acids via the
Maillard reaction, forming
advanced glycation end-products (AGEs), contributing aromas, flavors and texture to foods. One example of a dietary AGE is
acrylamide. Recent evidence suggests that the intestinal fermentation of dietary AGEs may be associated with
insulin resistance,
atherosclerosis,
diabetes and other inflammatory diseases. This may be due to the impact of AGEs on intestinal permeability. Starch gelatinization during cake
baking can be impaired by sugar competing for
water, preventing gelatinization and improving texture.
Starch sugars Starch can be
hydrolyzed into simpler carbohydrates by
acids, various
enzymes, or a combination of the two. The resulting fragments are known as
dextrins. The extent of conversion is typically quantified by
dextrose equivalent (DE), which is roughly the fraction of the
glycosidic bonds in starch that have been broken. These starch sugars are by far the most common starch based food ingredient and are used as sweeteners in many drinks and foods. They include: •
Maltodextrin, a lightly hydrolyzed (DE 10–20) starch product used as a bland-tasting filler and thickener. • Various
glucose syrups (DE 30–70), also called
corn syrups in the US, viscous solutions used as sweeteners and thickeners in many kinds of processed foods. •
Dextrose (DE 100), commercial glucose, prepared by the complete hydrolysis of starch. • High
fructose syrup, made by treating dextrose solutions with the enzyme
glucose isomerase, until a substantial fraction of the glucose has been converted to fructose. In the U.S.
high-fructose corn syrup is significantly cheaper than sugar, and is the principal sweetener used in processed foods and beverages. Fructose also has better microbiological stability. One kind of high fructose corn syrup, HFCS-55, is sweeter than
sucrose because it is made with more fructose, while the sweetness of HFCS-42 is on par with sucrose. •
Sugar alcohols, such as
maltitol,
erythritol,
sorbitol,
mannitol and
hydrogenated starch hydrolysate, are sweeteners made by reducing sugars.
Modified starches The modified food starches are
E coded according to
European Food Safety Authority and
INS coded Food Additives according to the
Codex Alimentarius: • 1400
Dextrin • 1401
Acid-treated starch • 1402
Alkaline-treated starch • 1403 Bleached starch • 1404
Oxidized starch • 1405 Starches, enzyme-treated • 1410 Monostarch
phosphate • 1412
Distarch phosphate • 1413
Phosphated distarch phosphate • 1414
Acetylated distarch phosphate • 1420
Acetylated starch • 1422
Acetylated distarch adipate • 1440
Hydroxypropyl starch • 1442
Hydroxypropyl distarch phosphate • 1443 Hydroxypropyl distarch glycerol • 1450
Starch sodium octenyl succinate • 1451 Acetylated oxidized starch INS 1400, 1401, 1402, 1403 and 1405 are in the EU food ingredients without an E-number. Typical modified starches for technical applications are
cationic starches,
hydroxyethyl starch,
carboxymethylated starches and thiolated starches.
Use as food additive As an additive for
food processing, food starches are typically used as thickeners and stabilizers in foods such as puddings, custards, soups, sauces, gravies, pie fillings, and salad dressings, and to make noodles and pastas. They function as thickeners, extenders, emulsion stabilizers and are exceptional binders in processed meats. Gummed sweets such as
jelly beans and
wine gums are not manufactured using a mold in the conventional sense. A tray is filled with native starch and leveled. A positive mold is then pressed into the starch leaving an impression of 1,000 or so jelly beans. The jelly mix is then poured into the impressions and put onto a stove to set. This method greatly reduces the number of molds that must be manufactured.
Resistant starch Resistant starch is starch that escapes digestion in the small intestine of healthy individuals. High-amylose starch from wheat or corn has a higher
gelatinization temperature than other types of starch, and retains its resistant starch content through
baking, mild
extrusion and other food processing techniques. It is used as an insoluble
dietary fiber in processed foods such as bread, pasta, cookies, crackers, pretzels and other low moisture foods. It is also utilized as a dietary supplement for its health benefits. Published studies have shown that resistant starch helps to improve insulin sensitivity, reduces pro-inflammatory biomarkers
interleukin 6 and
tumor necrosis factor alpha and improves markers of colonic function. It has been suggested that resistant starch contributes to the health benefits of intact whole grains.
Synthetic starch A cell-free
chemoenzymatic process has been demonstrated to synthesize starch from CO2 and hydrogen. The chemical pathway of 11 core reactions was drafted by
computational pathway design and converts CO2 to starch at a rate that is ~8.5-fold higher than starch synthesis
in maize. ==Non-food applications==